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Home lab setup

Deploys a k3s cluster with Ansible and Terraform backed by Flux and SOPS.

Overview

πŸ‘‹Β  Introduction

The following components will be installed in your k3s cluster by default. They are only included to get a minimum viable cluster up and running. You are free to add / remove components to your liking but anything outside the scope of the below components are not supported by this template.

Feel free to read up on any of these technologies before you get started to be more familiar with them.

For provisioning the following tools will be used:

  • Ubuntu - this is a pretty universal operating system that supports running all kinds of home related workloads in Kubernetes
  • Ansible - this will be used to provision the Ubuntu operating system to be ready for Kubernetes and also to install k3s

πŸ“Β  Prerequisites

πŸ’»Β  Systems

  • One or more nodes with a fresh install of Ubuntu Server 20.04. These nodes can be bare metal or VMs.
  • A Google Cloud account with a domain managed in Cloud DNS.
  • Some experience in debugging problems and a positive attitude ;)

πŸ”§Β  Tools

πŸ“ You should install the below CLI tools on your workstation. Make sure you pull in the latest versions.

Required

Tool Purpose
ansible Preparing Ubuntu for Kubernetes and installing k3s
direnv Exports env vars based on present working directory
flux Operator that manages your k8s cluster based on your Git repository
gnupg Encrypts and signs your data
go-task A task runner / simpler Make alternative written in Go
ipcalc Used to verify settings in the configure script
jq Used to verify settings in the configure script
kubectl Allows you to run commands against Kubernetes clusters
pinentry Allows GnuPG to read passphrases and PIN numbers
sops Encrypts k8s secrets with GnuPG

Optional

Tool Purpose
helm Manage Kubernetes applications
kustomize Template-free way to customize application configuration
pre-commit Runs checks pre git commit
prettier Prettier is an opinionated code formatter.

⚠️  pre-commit

It is advisable to install pre-commit and the pre-commit hooks that come with this repository. sops-pre-commit will check to make sure you are not by accident committing your secrets un-encrypted.

After pre-commit is installed on your machine run:

pre-commit install-hooks

πŸ“‚Β  Repository structure

The Git repository contains the following directories under cluster and are ordered below by how Flux will apply them.

  • base directory is the entrypoint to Flux
  • crds directory contains custom resource definitions (CRDs) that need to exist globally in your cluster before anything else exists
  • core directory (depends on crds) are important infrastructure applications (grouped by namespace) that should never be pruned by Flux
  • apps directory (depends on core) is where your common applications (grouped by namespace) could be placed, Flux will prune resources here if they are not tracked by Git anymore
cluster
β”œβ”€β”€ apps
β”‚   β”œβ”€β”€ default
β”‚   β”œβ”€β”€ networking
β”‚   └── system-upgrade
β”œβ”€β”€ base
β”‚   └── flux-system
β”œβ”€β”€ core
β”‚   β”œβ”€β”€ cert-manager
β”‚   β”œβ”€β”€ metallb-system
β”‚   β”œβ”€β”€ namespaces
β”‚   └── system-upgrade
└── crds
    └── cert-manager

TODO

Run these steps manually for now.

Add system user to Ansible

sudo adduser --uid 568 --group --system --disabled-password --no-create-home media

πŸš€Β  Lets go!

πŸ“ All of the below commands are run on your local workstation, not on any of your cluster nodes.

πŸ”Β  Setting up GnuPG keys

πŸ“ Here we will create a personal and a Flux GPG key. Using SOPS with GnuPG allows us to encrypt and decrypt secrets.

  1. Create a Personal GPG Key, password protected, and export the fingerprint. It's strongly encouraged to back up this key somewhere safe so you don't lose it.
export GPG_TTY=$(tty)
export PERSONAL_KEY_NAME="First name Last name (location) <email>"

gpg --batch --full-generate-key <<EOF
Key-Type: 1
Key-Length: 4096
Subkey-Type: 1
Subkey-Length: 4096
Expire-Date: 0
Name-Real: ${PERSONAL_KEY_NAME}
EOF

gpg --list-secret-keys "${PERSONAL_KEY_NAME}"
# pub   rsa4096 2021-03-11 [SC]
#       772154FFF783DE317KLCA0EC77149AC618D75581
# uid           [ultimate] k8s@home (Macbook) <[email protected]>
# sub   rsa4096 2021-03-11 [E]
  1. Create a Flux GPG Key and export the fingerprint
export GPG_TTY=$(tty)
export FLUX_KEY_NAME="Cluster name (Flux) <email>"

gpg --batch --full-generate-key <<EOF
%no-protection
Key-Type: 1
Key-Length: 4096
Subkey-Type: 1
Subkey-Length: 4096
Expire-Date: 0
Name-Real: ${FLUX_KEY_NAME}
EOF

gpg --list-secret-keys "${FLUX_KEY_NAME}"
# pub   rsa4096 2021-03-11 [SC]
#       AB675CE4CC64251G3S9AE1DAA88ARRTY2C009E2D
# uid           [ultimate] Home cluster (Flux) <[email protected]>
# sub   rsa4096 2021-03-11 [E]
  1. You will need the Fingerprints in the configuration section below. For example, in the above steps you will need 772154FFF783DE317KLCA0EC77149AC618D75581 and AB675CE4CC64251G3S9AE1DAA88ARRTY2C009E2D

☁️  Google Cloud Service Account

gcloud iam service-accounts create dns01-solver --display-name "dns01-solver"
gcloud projects add-iam-policy-binding $PROJECT_ID --member serviceAccount:dns01-solver@$PROJECT_ID.iam.gserviceaccount.com --role roles/dns.admin
gcloud iam service-accounts keys create key.json --iam-account dns01-solver@$PROJECT_ID.iam.gserviceaccount.com

πŸ“„Β  Configuration

πŸ“ The .config.env file contains necessary configuration files that are needed by Ansible, Terraform and Flux.

  1. Copy the .config.sample.env to .config.env and start filling out all the environment variables. All are required and read the comments they will explain further what is required.

  2. Once that is done, verify the configuration is correct by running ./configure.sh --verify

  3. If you do not encounter any errors run ./configure.sh to start having the script wire up the templated files and place them where they need to be.

⚑  Preparing Ubuntu with Ansible

πŸ“ Here we will be running a Ansible Playbook to prepare Ubuntu for running a Kubernetes cluster.

  1. Ensure you are able to SSH into you nodes from your workstation with using your private ssh key. This is how Ansible is able to connect to your remote nodes.

  2. Install the deps by running task ansible:deps

  3. Verify Ansible can view your config by running task ansible:list

  4. Verify Ansible can ping your nodes by running task ansible:adhoc:ping

  5. Finally, run the Ubuntu Prepare playbook by running task ansible:playbook:ubuntu-prepare

  6. If everything goes as planned you should see Ansible running the Ubuntu Prepare Playbook against your nodes.

β›΅Β  Installing k3s with Ansible

πŸ“ Here we will be running a Ansible Playbook to install k3s with this wonderful k3s Ansible galaxy role. After completion, Ansible will drop a kubeconfig in ./provision/kubeconfig for use with interacting with your cluster with kubectl.

  1. Verify Ansible can view your config by running task ansible:list

  2. Verify Ansible can ping your nodes by running task ansible:adhoc:ping

  3. Run the k3s install playbook by running task ansible:playbook:k3s-install

  4. If everything goes as planned you should see Ansible running the k3s install Playbook against your nodes.

  5. Verify the nodes are online

kubectl --kubeconfig=./provision/kubeconfig get nodes
# NAME           STATUS   ROLES                       AGE     VERSION
# k8s-0          Ready    control-plane,master      4d20h   v1.21.5+k3s1
# k8s-1          Ready    worker                    4d20h   v1.21.5+k3s1

πŸ”ΉΒ  GitOps with Flux

πŸ“ Here we will be installing flux after some quick bootstrap steps.

  1. Verify Flux can be installed
flux --kubeconfig=./provision/kubeconfig check --pre
# β–Ί checking prerequisites
# βœ” kubectl 1.21.5 >=1.18.0-0
# βœ” Kubernetes 1.21.5+k3s1 >=1.16.0-0
# βœ” prerequisites checks passed
  1. Pre-create the flux-system namespace
kubectl --kubeconfig=./provision/kubeconfig create namespace flux-system --dry-run=client -o yaml | kubectl --kubeconfig=./provision/kubeconfig apply -f -
  1. Add the Flux GPG key in-order for Flux to decrypt SOPS secrets
source .config.env
gpg --export-secret-keys --armor "${BOOTSTRAP_FLUX_KEY_FP}" |
kubectl --kubeconfig=./provision/kubeconfig create secret generic sops-gpg \
    --namespace=flux-system \
    --from-file=sops.asc=/dev/stdin

πŸ“ Variables defined in ./cluster/base/cluster-secrets.sops.yaml and ./cluster/base/cluster-settings.sops.yaml will be usable anywhere in your YAML manifests under ./cluster

  1. Verify all the above files are encrypted with SOPS

  2. If you verified all the secrets are encrypted, you can delete the tmpl directory now

  3. Push you changes to git

git add -A
git commit -m "initial commit"
git push
  1. Install Flux

πŸ“ Due to race conditions with the Flux CRDs you will have to run the below command twice. There should be no errors on this second run.

kubectl --kubeconfig=./provision/kubeconfig apply --kustomize=./cluster/base/flux-system
# namespace/flux-system configured
# customresourcedefinition.apiextensions.k8s.io/alerts.notification.toolkit.fluxcd.io created
# ...
# unable to recognize "./cluster/base/flux-system": no matches for kind "Kustomization" in version "kustomize.toolkit.fluxcd.io/v1beta1"
# unable to recognize "./cluster/base/flux-system": no matches for kind "GitRepository" in version "source.toolkit.fluxcd.io/v1beta1"
# unable to recognize "./cluster/base/flux-system": no matches for kind "HelmRepository" in version "source.toolkit.fluxcd.io/v1beta1"
# unable to recognize "./cluster/base/flux-system": no matches for kind "HelmRepository" in version "source.toolkit.fluxcd.io/v1beta1"
# unable to recognize "./cluster/base/flux-system": no matches for kind "HelmRepository" in version "source.toolkit.fluxcd.io/v1beta1"
# unable to recognize "./cluster/base/flux-system": no matches for kind "HelmRepository" in version "source.toolkit.fluxcd.io/v1beta1"
  1. Verify Flux components are running in the cluster
kubectl --kubeconfig=./provision/kubeconfig get pods -n flux-system
# NAME                                       READY   STATUS    RESTARTS   AGE
# helm-controller-5bbd94c75-89sb4            1/1     Running   0          1h
# kustomize-controller-7b67b6b77d-nqc67      1/1     Running   0          1h
# notification-controller-7c46575844-k4bvr   1/1     Running   0          1h
# source-controller-7d6875bcb4-zqw9f         1/1     Running   0          1h

πŸŽ‰ Congratulations you have a Kubernetes cluster managed by Flux, your Git repository is driving the state of your cluster.

☁️  Configure Cloudflare DNS with Terraform

πŸ“ Review the Terraform scripts under ./terraform/cloudflare/ and make sure you understand what it's doing (no really review it). If your domain already has existing DNS records be sure to export those DNS settings before you continue. Ideally you can update the terraform script to manage DNS for all records if you so choose to.

  1. Pull in the Terraform deps by running task terraform:init:cloudflare

  2. Review the changes Terraform will make to your Cloudflare domain by running task terraform:plan:cloudflare

  3. Finally have Terraform execute the task by running task terraform:apply:cloudflare

If Terraform was ran successfully head over to your browser and you should be able to access https://hajimari.${BOOTSTRAP_CLOUDFLARE_DOMAIN}

πŸ“£Β  Post installation

πŸ‘‰Β  Troubleshooting

Our wiki is a good place to start troubleshooting issues. If that doesn't cover your issue, start a new thread in the #support channel on our Discord.

πŸ€–Β  Integrations

Our Check out our wiki for more integrations!

🀝  Thanks

Big shout out to all the authors and contributors to the projects that we are using in this repository.

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